JP5503295B2 - Electronic control unit for automobile - Google Patents

Abstract

The device has a sensor i.e. force sensing resistor sensor, with a spiral shaped touch surface (1) assembled with a support (3) provided with a recessed or projected three-dimensional surface (4), where the sensor uses resistor that is sensitive to force. The surface (1) is fractioned in a manner that fractioned parts of the surface (1) are joined, at an assembled state, by adapting the shape e.g. tapered, spherical or conical shape, of the surface (4), to form a continuous touch surface.

Description

  The present invention relates to an electronic control device that controls an automobile via a contact-sensitive surface using a pressure-sensitive resistor element, for example, an electronic control device for an automobile that controls an electric mechanism that opens and closes at least one opening element.

  The present invention can be applied to control of electronic members for multimedia screens and air conditioning systems of automobiles.

  Recently, in order to perform these controls, a contact-sensitive surface capable of detecting a simple pressure with a driver's finger is used, based on the pressure detection position and / or the continuous movement of the pressure on the surface. It has been proposed to operate or control a part of a car in a particular form.

  For example, there are Patent Documents 1 to 3 as references. There are various types of these touch sensitive surfaces, and various techniques are used.

  Techniques using pressure sensitive resistor elements (also known as FSR “force sensing resistive element” sensors) are, for example, equivalent to using capacitive and other optical technologies in terms of ease of application and robustness. Exceeds technology.

  For example, such a sensor is known as a “digitizer pad” and is described as a prior art in Patent Documents 4-7.

  These sensors include, for example, a semiconductor layer sandwiched between a conductive layer and a resistance layer. Since the resistance value of the FSR layer decreases when pressure is applied, it is possible to measure the applied pressure and / or confirm where the pressure is applied by applying an appropriate voltage. It is.

French Patent Invention No. 2798329 Specification French Patent Invention No. 2800885 Specification US Pat. No. 6,157,372 U.S. Pat. No. 4,810,992 US Patent No. 5008497 French Patent Invention No. 2683649 European Patent No. 0541102

  The contact-sensitive surface of the FSR sensor has a planar shape that can be bent only slightly in the one-dimensional direction, and cannot be manufactured into an arbitrary three-dimensional shape.

  For user-friendly improvement in automobiles, in particular for improvement of control switches and keypads, a touch-sensitive surface sensor is integrated with a control device having an uneven three-dimensional surface, for example, a large or small curved surface shape. There is a need.

  In current touch-sensitive surface sensors, the curvature allowed in the active area of the sensor is small (the radius of curvature must be greater than 250 mm), limiting the choice of controller shape.

  An alternative is to cover the planar contact-sensitive surface sensor with a film, such as a silicone film, with a desired curved surface thickness on the control device to give the device a curved shape.

  Therefore, in order to obtain a control device having a curved surface shape, there is one in which a film having a thicker central portion than an edge portion is formed on the sensor. However, with such a configuration, the force is transmitted to the sensor through the thick part of the membrane, so the sensitivity of the sensor is reduced.

  An object of the present invention is to provide an automotive electronic control device including a contact-sensitive surface sensor that can maintain a uniform sensitivity to contact and have a three-dimensional shape.

  The subject of the present invention is an electronic control device for an automobile which is equipped with a sensor having a contact-sensitive surface using a pressure-sensitive resistor element, and which is assembled to a support having a three-dimensional surface with unevenness. At least a portion of the shaped contact-sensitive surfaces are intimately connected to each other according to the shape of the three-dimensional surface so that the surfaces are substantially continuous contact-sensitive surfaces in the assembled state. It is characterized by being shaped.

Another feature of the present invention is that
The shaped contact-sensitive surface has a predetermined number of arcuate strips arranged in a ring, and the contact-sensitive surfaces are brought into close contact with a support having a frustoconical concave surface; The small arch is connected to a disk-shaped common base.
The shaped contact-sensitive surface has a predetermined number of arcuate strips arranged in an annular arrangement, the contact-sensitive surfaces being in close contact with a support having a frustoconical concave surface; The large arch portion is connected to a common base having a parallelepiped shape.
The shaped contact-sensitive surface comprises 6 to 12, preferably 10 annularly arranged arcuate strips;
The shaped contact-sensitive surface has a convex dome surface, preferably a helical shape that closely contacts according to a substantially spherical support.
The shaped contact-sensitive surface has a spiral shape which is in close contact with a support having a substantially conical convex surface.
The shaped contact-sensitive surface has a predetermined number of trapezoidal strips, and the bottom of the strip is polygonal so that the contact-sensitive surface is in close contact with a support having a truncated polyhedral surface. Connected to a common base of shape.
The shaped contact-sensitive surface comprises four trapezoidal strips.
The shaped contact sensitive surface is provided with a connecting projection;

  Other advantages and features will become apparent upon reading the description of the invention with reference to the accompanying drawings.

1 is a perspective view of a sensor according to a first embodiment of the present invention, a support, and a sensor assembled to the support. It is a perspective view of the sensor assembled | attached to the sensor which concerns on the 2nd Embodiment of this invention, a support body, and a support body. FIG. 3a is a perspective view of a sensor according to a third embodiment of the present invention, and FIG. 3b is a perspective view of a support body assembled with the sensor. FIG. 4A is a perspective view of a sensor according to a fourth embodiment of the present invention, and FIG. 4B is a perspective view of a support body assembled with the sensor. FIG. 5a is a plan view of a support body assembled with a sensor according to a fifth embodiment of the present invention, and FIG. 5b is a perspective view of FIG. 5a.

  In these drawings, the same elements are denoted by the same reference numerals.

  The electronic control device for automobiles according to the present invention controls an electric mechanism (not shown) for opening and closing opening elements such as automobile windows, sunroofs, automobile trunks, tailgates, and electric sliding doors. Can do.

  Naturally, this device can also be applied to other electronic controls of the vehicle such as control of electric seats, lighting control such as dome-shaped reading lights and background lighting.

  FIG. 1 shows an electronic control apparatus for automobile according to the present invention. IA is before assembly and IB is after assembly.

  The device comprises a sensor having a contact sensitive surface 1 using a pressure sensitive resistor element and is assembled to a support 3 by, for example, adhesion.

  The support 3 has a concave or convex three-dimensional surface 4 such as a curved surface or a dish surface.

  The contact-sensitive surface 1 of the sensor is, for example, a three-dimensional surface 4 in which at least a part of the contact-sensitive surface 1 is formed so as to be a substantially continuous contact-sensitive surface 1 in a state assembled by bonding. It has a shape that is shaped so as to be closely connected to each other according to the shape.

  More precisely, the shaped touch-sensitive surface 1 has a predetermined number of arcuate strips 7 arranged in an annular shape, and the touch-sensitive surface 1 comes into close contact with a support 3 having a frustoconical concave surface 4. As described above, the small arch portion of the strip 7 is connected to the disk-shaped common base 9.

  In the assembled state (IB in FIG. 1), the edges of the contact sensitive surface 1 are connected to each other so as to form a substantially continuous contact sensitive surface 1 without gaps and without overlapping. ing. Thereby, it is possible to avoid the formation of bubbles and bumps of the adhesive that give the user an unpleasant feel.

  The shaped contact sensitive surface 1 is advantageously provided with, for example, a connecting projection 5 connected to a printed wiring board.

  2, 3a, 3b, 4a, 4b, 5a and 5b show four other embodiments of the control device according to the invention.

  2A shows a second embodiment before assembly, and IIB shows a second embodiment after assembly. The shaped touch-sensitive surface 1 has strips 7 having a predetermined number of arcuate shapes arranged in an annular shape. The contact-sensitive surface 1 has a large arch portion of the strip 7 connected to a common base 9 having a parallelepiped shape via a tongue-shaped portion 7 'so as to come into close contact with the support body 3 having the concave surface 4 having a truncated cone shape. Yes.

  In the two embodiments described above, it is advantageous if the shaped touch-sensitive surface 1 has 6 to 12, preferably 10 strips 7 of an arcuate shape arranged in an annular shape. In this case, the strip 7 is, for example, closely on one side along the keypad support surface and on the other hand exhibits a sufficient resolution.

  FIGS. 3 a, 3 b show a third embodiment in which the shaped contact-sensitive surface 1 has a helical shape that closely contacts according to a support 3 having a convex dome surface, preferably a substantially spherical surface 4.

  FIGS. 4 a and 4 b show a fourth embodiment in which the shaped contact-sensitive surface 1 has a helical shape that closely contacts according to a support 3 having a convex, substantially conical surface 4.

  In the fifth embodiment, the shaped contact-sensitive surface 1 has a predetermined number of trapezoidal strips 11 and comes into close contact with the support 3 having the truncated polyhedral uneven surface 4. A small bottom portion is connected to a common base 13 having a polygonal shape.

  5a and 5b show that the shaped contact-sensitive surface 1 has four isosceles trapezoidal strips 11 and the bottom of the strip 11 is polygonal so that it is in close contact with the concave support 3 The 5th Embodiment connected with the common base 13 of FIG.

  This configuration is particularly suitable for the production of keypad keys, for example.

  In the manufacture of the control device, the planar contact-sensitive surface 1 is first shaped. Next, the touch-sensitive surface 1 is assembled to the support 3 by, for example, adhesion so that the touch-sensitive surface 1 is in close contact with the three-dimensional shape of the support 3.

  The touch-sensitive surface 1 may first be preformed into a three-dimensional shape by, for example, a heat molding method.

  Next, the sensor assembled on the support 3 is covered with a film made of, for example, silicone in order to form an electronic control unit.

  It will be understood that such a control device can produce a control interface having a complicated uneven shape such as a curved surface and a three-dimensional shape without reducing the contact sensitivity.

DESCRIPTION OF SYMBOLS 1 Contact sensitive surface 3 Support body 4 Surface 5 Projection part 7 for connection, 11 Strip 9, 13 Common base

Claims (3)

An automotive electronic control device comprising a sensor having a contact-sensitive surface (1) using a pressure-sensitive resistor element and assembled to a support (3) having an uneven three-dimensional surface (4),
At least part of the shaped contact sensitive surface (1) is such that the contact sensitive surface (1) of the sensor is a substantially continuous contact sensitive surface (1) in the assembled state. Shaped to be closely connected to each other according to the shape of the surface (4) of
The electronically controlled automotive device characterized in that the shaped touch-sensitive surface (1) has a convex dome surface, preferably a helical shape that closely contacts according to a support (3) having a substantially spherical surface (4). . An automotive electronic control device comprising a sensor having a contact-sensitive surface (1) using a pressure-sensitive resistor element and assembled to a support (3) having an uneven three-dimensional surface (4),
At least part of the shaped contact sensitive surface (1) is such that the contact sensitive surface (1) of the sensor is a substantially continuous contact sensitive surface (1) in the assembled state. Shaped to be closely connected to each other according to the shape of the surface (4) of
The electronic control device for an automobile according to claim 1, wherein the shaped contact-sensitive surface (1) has a spiral shape that comes into close contact with the support (3) having a substantially conical convex surface (4). The shaped touch-sensitive surface (1) is an automobile electronic control device according to claim 1 or 2, characterized in that it comprises a connection protruding portion (5).

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